NL9000269A - DEVICE FOR DRIVING AN ELECTRIC RICE COOKER. - Google Patents

Description

Device for controlling an electric rice cooker

The invention relates to a device for controlling an electric rice cooker, more particularly a device for accurately controlling the temperature and time for cooking rice and keeping the cooked rice warm by means of a program that is in a microprocessor is stored. The electric rice cooker of the present invention has separate heating elements, which act consecutively as a first boiling heating element, a second boiling heating element and a third heating element for keeping the cooked rice warm.

Conventional electric rice cookers have a power switch lever that switches on the automatic temperature switch located under the inner pot. This switch connects the cooking heating element to the mains.

In conventional electric rice cookers, the temperature of the pot suddenly rises after the rice has been cooked, so that all the water in the pot has been used. When the temperature rises above the Curie point of a ferrite from the automatic temperature switch, the ferrite loses its magnetic properties and the switch opens. This disconnects the cooking heating element from the net, causing the temperature in the inner pot to drop. When this temperature falls below a predetermined temperature for keeping the inner pot warm, the TRC switch (which is a special switch for keeping the pot warm) switches automatically and connects the warming element to the net, so that the warming element connects the inner pot to a predetermined temperature keeps warm.

Conventional electric rice cookers therefore only work well to a certain extent. They are automatically disconnected from the net after the rice has been cooked and keep the cooked rice warm at a constant temperature, but because the TRC switch has a high tolerance to its working temperature, the switch sometimes closes at a temperature higher than the predetermined level. Certain conventional electric rice cookers therefore become so hot that the rice is burned, causing the rice to scorch and stick to the bottom of the inner pot.

Other electric rice cookers are disconnected from the mains before the rice is properly cooked, because the TRC switch opens at a temperature below the predetermined level. For both these reasons, conventional electric rice cookers operate relatively unsatisfactorily.

The TRC switch, which is used to keep the rice warm, has a high tolerance to its working temperature and can therefore be activated at a temperature different from the temperature selected for keeping warm. As a result, the rice in the inner pot gets spoiled or hardens.

Since the automatic temperature switch of the conventional electric rice cookers is operated by a mechanical lever, which requires a considerable installation space, the known rice cookers are relatively bulky.

In order to obtain a good taste and smell of the cooked rice, it is necessary to soak the rice in water for some time before cooking, and steam the cooked rice afterwards. In the known rice cookers, a constant electric power is supplied to the heating element of the rice cooker during cooking. As a result, the rice can be cooked in the known rice cooker without being soaked sufficiently before cooking and further burning because the rice is not steamed after cooking.

In order to solve these problems, some known electric row ducts use more than one heating element. The heating elements are connected with thermal bimetal switches with different operating temperatures.

Also some of these heating elements have a lever operated microswitch. When the lever is pressed, the micro switch is switched on and only the heating elements connected to this micro switch are connected to the mains. The temperature generated by the heating elements connected only to the microswitch is low and the temperature of the inner pot rises slowly, allowing sufficient soaking time for the rice in the pot before cooking.

When the temperature of the pot rises to the level at which the rice boils, the thermal bi-metal switches are activated and all heating elements of the rice cooker are connected to the mains to cook the rice in the pot. When the temperature of the inner pot suddenly rises after the rice has been boiled, because all the water has been consumed, another thermal bimetal switch is activated, in order to change the connection of the heating elements, i.e. from a parallel circuit to a series circuit . The temperature generated by the modified connection of the heating elements is low and maintains a constant level suitable for steaming the cooked rice. These conventional electric rice cookers therefore have a function of both soaking the rice in water before cooking and steaming the cooked rice afterwards. However, the thermal bimetal switches have a large tolerance in their operating temperature. This great tolerance also contributes to the problems described above in cooking rice. Since the known rice cookers do not have a timer to control the cooking time, soaking the rice before cooking and steaming it after cooking are only controlled by the temperature of the inner pot and cannot take place as accurately as would be desired .

Another problem with conventional rice cookers is that they only work in a single order. It is therefore not possible to cook the rice without soaking it first. (Sometimes it is desirable to cook the rice immediately and skip the rice soaking procedure.)

Another problem with the known electric rice cookers is that they require a special manual switch, which can be adapted to both 100 V and 220 V mains voltage.

The main object of the present invention is to provide an electric rice cooker control device which controls the rice soaking time and steaming time of the cooked rice and functions accurately at predetermined temperatures.

Another object of the present invention is to provide a control device which operates at both a mains voltage of 100 and 220 V without the need for a manually operated switch. Another object of the invention is to provide a control device which has two operating modes, which are defined below.

According to a first aspect of the present invention there is provided an apparatus for controlling an electric rice cooker which includes a temperature detecting means for detecting the temperature of the inner pot of the rice cooker, a switching means for a boiling heating element for connecting boiling heating elements 1 to the mains, a switching element for a warming element for connecting a heating element to the mains, a switching signal generating means for generating a switching signal for switching the switching elements at times which are synchronized with a zero crossing of the net, and a microprocessor, which is connected to each of the organs and controls all of the organs.

According to the invention, the device can operate with a mains voltage of 100 resp. 220 V without a manual switch present. A voltage sensing circuit is provided, which determines whether the mains voltage is 100 or 220 V. The microprocessor controls the switching circuit in such a way that the electrical power supplied to the boiling heating element or the keeping warm element is kept constant regardless of the AC voltage of the mains.

According to another aspect of the present invention, the device can control the rice cooker such that rice can be cooked by two cooking methods described below. A mode selection circuit has been installed for this purpose.

According to another aspect of the invention, a method of controlling an electric rice cooker is provided, in which the mains supply of the cooking heating element is switched on and off, in order to increase the temperature of the inner pot to the first predetermined temperature, the mains power is turned off during a first predetermined interval, which is necessary to drop the temperature of the inner pot from the first predetermined temperature to a second predetermined temperature, controlling the mains power to change the temperature of the inner pot to the second predetermined level during a second predetermined interval, which is necessary for soaking the rice, connecting the mains supply to the boiling heating elements, in order to increase the temperature of the inner pot to a third predetermined value, while rice is being cooked, switching off the power supply for the boiling heating elements during a third predetermined interval, switching on and off the mains supply for the boiling heating elements and the keep-warm element during a fourth predetermined interval, which is required for steaming the cooked rice at a lower temperature and supplying the mains supply to the warming element, in order to keep the inner pot at a fourth predetermined temperature.

The invention is explained in more detail below with reference to the drawing, in which an exemplary embodiment is shown.

Fig. 1 shows the diagram of an embodiment of the device for controlling an electric rice cooker according to the invention.

Fig. 2A-2J show flow charts for the operation of the electric rice cooker control device.

Fig. 3A shows the variations in the energy consumption and the temperature of the inner pot, when an electric rice cooker is controlled by the device according to the invention according to cooking method 1.

Fig. 3B shows variations in the energy consumption and the temperature of the inner pot, when an electric rice cooker is controlled by the device according to the invention according to cooking method 2.

Fig. 1 shows the schematic of an embodiment of the device for controlling an electric drive shaft.

As shown in Fig. 1, the control circuit is provided with a temperature detection circuit 101 for detecting the temperature of an inner pot of the electric rice cooker, a switching circuit 102 for a boiling heating element for connecting boiling heating elements to the AC mains, a switching circuit 103 for keeping warm elements for connecting a keeping warm element to the AC mains, a switching signal generating circuit 104 for generating a switching signal for switching the switching members at a time which is synchronized with a zero crossing of the mains AC voltage, a voltage detecting circuit 105 for detecting the voltage of the AC mains, a mode selection circuit 106 for selecting a cooking method, an indicator circuit 107 for indicating the condition of the electric rice cooker, a microprocessor 108, which is connected to each of the circuits, and a reset circuit 109, that w Is used to manually reset the microprocessor or set the electric rice cooker to a keep warm mode when a power failure recovery is performed.

The temperature detection circuit 101, which detects the temperature of the inner pot of the electric rice cooker, comprises a thermistor Th and a resistor R20 connected in series with it, two comparators IC1 and IG2, the inverting inputs of which are connected in parallel with the thermistor Th, a first voltage divider with two resistors R18 and R19, the node of which is connected to the non-inverting input of the comparator IC1, a second voltage divider with resistors R16 and R17, the node of which is connected to the non-inverting input of the comparator IC2, a first temperature setting circuit with the series circuit of a diode D17 and a resistor R9, the anode of the diode D17 being connected to the non-inverting input of the comparator IC1 and a terminal of the resistor R9 being connected to the terminal D3 of the microprocessor 108, a second temperature setting circuit with the series circuit of a diode D18 and a resistor R10 wherein the anode of the diode D18 is connected to the non-inverting input of the comparator IC2 and a terminal of the resistor R10 is connected) to the terminal D2 of the microprocessor 108.

The outputs of the comparators IC1 and IC2 are resp. connected to terminals G2 and G3 of microprocessor 108.

The values of the resistors RIO, R16, R17, R20 i and the thermistor Th are chosen so that the output of the comparator IC2 is inverted when the output of the terminal D2 is logic 0 and the temperature of the inner pot 160 C or when the output is logic 1 and the

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temperature is 50 ° C.

The value of the resistors R9, R18, R19, R20 and the thermistor Th is chosen such that the output of the comparator IC2 is inverted when the output of the terminal D3 is logic 0 and the temperature of the indoor

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pot 140 C or when the output is logic 1 and the

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The temperature is 70 ° C.

The temperature detection circuit 101 can therefore determine the temperature of the inner pot at intervals defined by two comparators and two temperature setting circuits.

There are two boiling heating elements H1 and H2, which must be controlled by the control circuit of the electric rice cooker according to the invention.

The cooking heating element switching circuit 102 comprises two triacs TC1 and TC2, which are connected in series with resp. boiling heating element H1 and H2, two transistors Q1 and Q2, whose emitters are resp. are connected to the gates of the triacs TC1 and TC2 and whose bases are connected to the terminals L3 and L4 of the microprocessor 108 via resistors R4, respectively. R5. The two boiling heating elements H1 and H2 are controlled such that the thermal energy generated by the heating elements is constant regardless of the voltage of the alternating current network. If the voltage of the mains is 100 V, the microprocessor 108 supplies a logic 1 to the terminals L3 and L2. The two triacs TCl and TC2 are turned on via transistors Q1 and Q2, because transistors Q1 and Q2 are turned on by the signal from terminals L1 and L2. Both boiling heating elements are therefore energized at a mains voltage of 100 V and supply thermal energy according to their capacity, i.e. 850 W.

If the mains voltage is 220 V, the microprocessor 108 supplies a logic 1 to connection L3. Only one triac TC2 is switched on and the heating element H2 is energized with a mains voltage of 220 V. However, the thermal energy generated by the heating element H2 at a mains voltage of 220 V is equal to that generated by two heating elements at 100 V mains voltage is generated. The boiling heating elements, which are controlled by the control circuit according to the invention, therefore generate a constant thermal energy independent of the voltage of the alternating current network and the electric rice cooker is suitable for use at both 100 and 220 V mains voltage.

The keep-warm switching circuit 103 comprises a keep-warming element H3, a series-connected triac TC3, a transistor Q3, the emitter of which is connected to the gate of the triac TC3 and the base of which is connected to the terminal L1 of the microprocessor 108 via the resistor R6. If the voltage of the alternating current network is 100 V, the microprocessor 108 supplies a signal to the terminal L1 and this signal switches on the gate of the triac TG3 via the transistor Q3. When the triac TC3 is switched on, a mains voltage of 100 V is supplied to the warming element H3 and the temperature of the inner pot remains at a predetermined level, in order to keep the pot warm.

If the voltage of the AC network is 220 V.

microprocessor 108 provides a signal to terminal LI every five cycles of the alternating current. The triac TC3 can therefore be switched on during one cycle of every five cycles of the AC voltage and the thermal energy obtained at a mains voltage of 220 V is the same as at 100 V.

The start signal generating circuit 104 comprises a transistor Q4, the collector of which is connected to the terminal GO of the microprocessor 108 and whose base is connected to the mains via a series circuit of a resistor Ril and a capacitor C4, and a zener diode ZD, which is connected between the base of the transistor Q4 and ground.

A square pulse is generated across the zener diode ZD during a positive half cycle of the AC voltage.

The square pulse is therefore synchronized with a zero crossing of the AC voltage. This synchronized pulse is used to start the switching circuits 102 and 103 in the zero crossing of the AC voltage.

The voltage detection circuit 105 includes a first voltage divider with resistors R14 and R15, a comparator IC3, the inverting input of which is connected to the first voltage divider, and a second voltage divider with resistors R12 and R13, the output signals of which are applied to the non-inverting input of the comparator IC3. The output voltage of the first voltage divider is fixed, but the output voltage of the second voltage divider is proportional to the voltage of the mains. The output of the comparator IC3 is connected to the terminal G1 of the microprocessor 108.

The voltage detecting circuit 105 is designed such that the output of the comparator IC3 is logic 0 when the mains voltage is 100 V and logic 1 when the mains voltage is 220 V. A mode selection circuit 106, which serves to determine the cooking state of the electric rice cooker, includes two switches SW2 and SW3. Switch SW2 is connected between terminal S1 of microprocessor 108 and ground while switch SW3 is connected between terminal L0 of microprocessor 108 and ground. These two switches determine two cooking methods of the electric rice cooker. Method 1 is the cooking state where rice is cooked and the cooked rice is steamed. Method 2 is the cooking state, where rice is soaked in water, the soaked rice is boiled, and the cooked rice is steamed.

The indicator circuit 107 comprises light-emitting diodes (LED) D11, D12, D13 and D14, the cathodes of which are connected to each other and grounded through a resistor R3, which resistor R3 serves as a current limiter, and furthermore light-emitting diodes D15 and D16 and series resistors R7 connected in series therewith. R8. The anodes of the diodes D11, D12, D13 and D14 are respectively. connected to terminals L7, L6, L5 and L4 of microprocessor 108. The r cathodes of diodes D1 and D16 are connected to terminals D0 and D1, respectively. D1 of the microprocessor 108. When the electric rice cooker operates in mode 1, the microprocessor 108 illuminates the diode (LED) Dl1. If the electric rice cooker operates in mode 2, the microprocessor 108 illuminates the diode (LED) D12.

Steam indicator D13 of the indicator circuit 107 is a light-emitting diode, indicating that the electric rice cooker is steaming the cooked rice. An indicator D14 for 220 V of the indicator circuit 107 is a light-emitting diode, which indicates that the voltage of the AC mains is 220 V, and an indicator D15 for 100 V of the indicator circuit 107 is a light-emitting diode, which indicates that the voltage of the AC network is 100 V.

Heating indicator D16 of the indicator circuit 107 is a light-emitting diode, which indicates that the electric rice cooker is heating the steamed rice. Each LED of the indicator circuit 107 is controlled by a signal supplied from the microprocessor 108 according to the cooking state of the electric rice cooker.

The reset circuit 109 comprises a switch SW1, a capacitor C1 connected in parallel and a resistor R1 connected in series with the parallel circuit of SW1 and C1. The voltage across capacitor C1 is applied to terminal 4 of microprocessor 108. Microprocessor 108 is of type COM 420L and available from National Semiconductor Co., USA.

2A-2J show flow charts of the program for the operation of the control device according to the invention.

A micro switch MSW is opened when the inner pot is placed in the electric rice cooker and is connected in parallel to the thermistor Th.

The microswitch therefore makes it possible to protect the inner pot from overheating when the inner pot is placed in the electric rice cooker in a condition where the power supply is supplied to the heating elements and the mode selection switches 5 are operated.

The block 110 serves to reset the microprocessor 108 for the first time and the block 111 is a voltage regulator with a voltage regulator CVG constructed as an integrated circuit. Each of numbers 3-28 is a pin number of microprocessor 108.

The operation of an electric rice cooker according to the present invention is as follows: A. Cooking method selection or mode selection> When the electric rice cooker is connected to the mains, DC voltages Vcc and Vdd are supplied to each part of the control device.

As shown in Fig. 2A, a mode selection is made first. Starting with START step A1 follows step A2 for initializing the RAM of microprocessor 108. The program continues with step A3 where microprocessor 108 provides a logic 0 at its terminal D1 and a logic 1 at its terminal GO. This logic 0 illuminates the indicator LED D16, which indicates that the tube i is in mode 3 and the temperature of the inner pot at a

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maintains predetermined keep warm level, for example 70 ° C and the logic 1 of terminal GO causes microprocessor 108 to generate synchronized pulses which are used to start switching circuits 102 and 103 in the zero crossings of the AC voltage.

At step A4, the program stores 3 in the MODE memory,

At step A6, the program decides whether or not the input signal at connection G1 is logic 1 (which corresponds to 220 V AC voltage). If yes, the program logically delivers 1 to terminal DO (step A8) and terminal L4 (step AIO). Since the logic output signal of terminal DO is 1, the indicator diode D15 for a mains voltage of 100 V is switched off. The indicator diode D14 for 220 V is switched on, because the logic level of the connection L4 is 1.

If the input signal at terminal G1 is not logic 1, the program goes from step A6 to step A7.

In steps A7 and A9, microprocessor 108 supplies a logic zero to terminals DO and L4. This means that the 100 V indicator diode D15 is energized and the 220 V indicator diode D14 is turned off.

In step All, the program determines whether the contents of the memory are MODE 3. Since MODE is set to 3 at step A4, the program advances to step A12. If MODE is not 3, the program jumps to step A22.

In step A12, the program determines whether or not the input signal at terminal L0 of microprocessor 108 is logic 0. If this is not the case, it means that the tube is not in mode 2. The program proceeds to step A13 where the program determines whether the input signal at terminal SI is logic 0.

Because the logic 0 at connection SI at step A13> means that the tube is in mode 1, the program proceeds to step Al5. The microprocessor stores 1 in memory MODE at step A15 and 0 in memory SM0D at step A17. Then, at steps A19 and A21, microprocessor 108 supplies a logic 1 to terminals D1 and L7 to illuminate both the keep warm indicator D15 and mode 1 indicator D11.

If the result at step A13 is false, the program jumps directly to step A22.

If the result at step Al2 is true, the electric rice cooker is in mode 2. The program therefore proceeds to step A14, where the memory MODE is set to 2. The memory SMOD is set to 0 at step Al6. According to steps Al8 and A20, microprocessor 108 supplies a logic 1 to terminals D1 and L6, so that mode 2 indicator diode D12 is energized and the keep-warm indicator diode D16 is turned off.

Then, the program goes to step A22.

If the result at step A6 is false, the program jumps directly to step A22.

In step A22, the microprocessor 108 provides one

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logic 0 at connection D2 to set 160 ° C as predetermined temperature for the inner pot. In step A23, the program decides whether or not the input signal at terminal G2 is logic 0, which means that the temperature

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the inner pot is less than 160 ° C.

If yes, the program proceeds to step A25 to determine a cooking state. If not, because the temperature

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The inner pot temperature is above 160 C, which means that the electric rice cooker is in a fault condition, the program goes to step A24, where the memory MODE is set to 3. Steps A25-A29 serve to determine what the cooking is fashion.

B. Operation in mode 1

If the switch SW2 is pressed to select mode 1, in which the soaking of the rice is eliminated and the rice is cooked quickly, the indicator diodes Dll for mode 1 and one of the mains indicator diodes Dl4 or Dl5 are lit and the memory becomes MODE set to 1 and the memory SMOD to 0, as described above. Then, the microprocessor 108 goes to step E2.

In step E2, the program determines whether a logic 0 is stored in the memory SMOD. If yes, the content of SMOD is changed to logic 1 in step E3 and the program jumps directly to step A5 and continues according to the subsequent sequence. When the program returns to step All, SMOD is not 3 but 1. Therefore, the program jumps to step A22 and goes from step A22 to step A23.

In step A23, the program again determines whether the temperature

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of the inner pot is less than 160 C. When the program reaches step A25, 1 is stored in memory MODE. The program therefore goes to step A26, which is the same as step E1 from step A25.

Since SMOD is set to 1, the program goes through steps E1, E2 and E4 and reaches step E5, where microprocessor 108 supplies a logic 0 to terminal D3,

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(to choose 140 C as the predetermined temperature for the temperature sensing circuit.

in step E6, the program or input signal determines at the terminal G3 of the microprocessor 108

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logic 1. The temperature of the inner pot cannot reach 140 C, because the boiling heating elements are not yet connected to the mains. The program therefore moves from step E6 to subroutine TRC1.

The subroutine TRC1 of step D100 starts with a confirmation step D200 to determine whether the voltage of the mains is 220 or 100 V. At step D200, the voltage of the network is determined by determining whether the input signal at terminal G1 of the microprocessor 108 is logic 1.

If the mains voltage is 100 V, i.e. the input signal at G1 is logic 0, the microprocessor 108 supplies a logic 1 to terminals L2 and 13 (steps D300 and D400) for energizing the boiling heating elements H1 and H2. Both boiling heating elements are connected to the mains voltage 100 V and generate heat according to their power capacity, i.e. 850 W, the program jumps to step A5 and the next steps are resumed.

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until the temperature of the inner pot rises to 140 ° C.

If, on the other hand, the input signal at terminal G1 in the subroutine TRC1 is logic 1, i.e. the mains voltage is 220 V, the program goes to step D50Q from step D200 and the microprocessor 108 supplies a logic 1 to terminal L3. This logic 1 energizes the boiling heating element H2. As described above, the power consumption of the boiling heating element at a mains voltage of 220 V is also 850 W as in the case of the two boiling heating elements H1 and H2, when a mains voltage of 100 V is supplied. The program then proceeds to step A5 and the subsequent sequence energizes the boiling heating element H2 until the temperature of the

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inner pot rises to 140 ° C.

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When the temperature of the inner pot reaches 140 C, which means that the cooking of the rice is finished, the input signal on terminal G3 changes to logic 1. The program goes to step E7, where microprocessor 108 provides a logic 0 to terminal L7 and logic 1 to terminal L5, to ignite the steam indicator diode D14 and turn off the diode D11 for mode 1 (steps E7 and E8).

In step E9, the program stores a 2 in the memory SMOD and jumps to step A5. The following steps are repeated as previously described.

When the program reaches step E4, the memory SMOD has already recorded a 2 instead of a 1.

Therefore, the program proceeds to the next confirmation step Eli and then to step E12. The operation in step E12 is a routine for determining whether the loop including step E12 is performed for three minutes. If no, the program immediately jumps to step A5 and waits three minutes without energizing the heating elements. If the three minute routine has ended, the program goes to step E13 from the routine of step E12.

The memory SMOD is set to 3 at step E13 and a memory PMOD is set to 1 at step E14. Then, the program proceeds to step A5 and the following steps repeat in the manner previously described. When the program reaches the step Eli, SMOD has already changed to 3. The program therefore moves to the next subroutine of step F1 from the step Eli.

Since SMOD 3 is recorded, the program goes from step F2 to a three minute routine according to step F3. If the loop with step F3 is performed for less than three minutes, the program goes from step F3 to step F4.

Since the contents of the memory are PMOD 1, the result of step F4 is true and the program goes to step F5. The operation of step F5 includes an eight-second routine so that the microprocessor 108 can run the loop with step F5 for eight seconds without performing any new operation. If the eight second routine has not ended, the program jumps directly to subroutine TRC2 of step C100, where the warming element H3 is energized for the first eight seconds.

The subroutine TRC2 starts with the confirmation step 3 C100 and determines in step C200 whether the mains voltage is 220 or 100 V. If the input signal of the terminal G1 is logic 0, which means that the mains voltage is 100 V, the program goes to step C300, where the microprocessor 108 supplies a logic 1 to terminal L1, in order to energize the keep-warm element H3. If the result of step C200 is false, the program goes to step C400.

The operation of step C400 is a modulo-5 counter, which provides a pulse every five cycles of the 220 V AC. Step C500 is to supply a logic 1 to the terminal LI of the microprocessor 108 for every five cycles of 220 V AC according to the pulse of step C400. The microprocessor 108 therefore energizes the keep-warm element H3 for one cycle of every five cycles of the alternating voltage of 220 V, so that the heat generated by the keep-warm element H3 is kept at a constant temperature for eight seconds regardless of the voltage of the mains.

If the eight second routine in step F5 is terminated, the program proceeds to step F6, where the memory PMOD is set to 0. Then, the program proceeds to step A5 and the following steps are repeated.

When the program reaches step F4, the content of SM0D is not 1 but 0. Therefore, the program moves to another eight-second routine in step F6. The program jumps directly to step A5 without energizing the heaters until the eight-second routine according to step F7 is completed.

If the routine of step F7 has ended, the program proceeds to step F8, where the memory PMOD is set to 1. When the program proceeds to the following steps and reaches step F4, the contents of the memory are SMOD 1 instead of 0. The program therefore goes to step F5 to energize the heating element for eight seconds. The procedure for energizing the heating element for eight seconds, as defined in step F5, and not energizing it for the next eight seconds, as defined in step F7, repeats itself for three minutes, as defined) in step F3.

When the three-minute routine in step F3 has ended, the program goes to step F9, where SMOD is set to 4 and jumps to step A5. When the program reaches step F2, the contents of memory SMOD is 4> instead of 3 and the program then goes to step F10.

Step F10 includes a nine minute routine that determines whether the direct jump loop from step F10 to step A5 is performed for nine minutes. If not, the program jumps directly to step A5 to continue steaming the cooked rice.

When the nine-minute routine from step F10 has ended, the program goes to step Fll, where the memory MODE is set to 3.

In steps F12 and F13, the microprocessor i 108 supplies a logic 0 to terminals D1 and L5. These output signals energize the keep-warm indicator diode Dl5 and turn off the steam-indicator diode D13. Then the program goes to step A5, where the electric rice cooker is controlled according to mode 3, keeping the rice warm.

The steaming of the cooked rice is therefore continued for fifteen minutes. The variation of the energy consumption and the variation of the temperature of the inner pot are shown in Fig. 3A.

1 The interval between tO and tl is for cooking rice and the interval between tl and t2 is a waiting state of three minutes after the rice has been cooked.

The interval between t2 and t3 is three minutes before switching on and off the power supply for the warming element H3.

The interval between t3 and t4 is a waiting state of nine minutes. After t4 the electric rice cooker is turned to O .....

kept a constant temperature, for example 70 C, which is suitable for keeping the inner pot warm.

The interval for steaming the cooked rice is therefore fifteen minutes between t1 and t4.

C. Operation in mode 2

As described above, mode 2 is defined as a cooking state, wherein the heating elements are energized to thoroughly soak rice in water, cook the soaked rice, and steam the cooked rice.

If the switch SW2 of the mode selection circuit 106 is turned on, the memory MODE is set to 2 in step A14 and mode 2 is selected when the program reaches step A27.

The program therefore moves from step A27 to step A28, which is equivalent to step G100 of Fig. 2G.

The procedure for mode 2 begins with step G200, where the program determines whether the contents of the memory are SMOD 0. If the result is true, the program proceeds to step G300, where microprocessor 108 has a logic 1 on it

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terminal D2 supplies and selects 50 ° C as the predetermined temperature for the temperature sensing circuit 101.

In step G310, the program determines whether the input signal at terminal G2 of the microprocessor 108 is logic 1. If no, it means that the temperature of the

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inner pot is less than 50 C and as a result, the program proceeds to the next acknowledgment step G320, where the program determines whether the contents of the memory are PMOD 1.

If specified in PMOD 1, the program proceeds to step G330, where the program determines whether an eight-second routine has ended. If no, the program goes to TRC1 from step D100, in order to energize the heating element, as in case of mode 1. If the eight second routine of step G330 has ended, the noamam goes from default G330 to default G35Q. where the content of the memory PMOD is set to logic 0 and jumps to step A5. When the program reaches step G320, the contents of the memory PMOD is 0 instead of 1, so that the program moves from step G330 to step G360, which includes another eight-second routine for de-energizing the heaters for eight seconds . Both of these eight-second routines repeat until the

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temperature of the inner pot reaches 50 ° C.

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When the temperature of the inner pot reaches 50 ° C, the input signal at terminal G2 of the microprocessor 108 is changed to logic 1. Thus, the program goes from step G310 to step G380, where the memory SMOD is set to 1 and jumps to step A5.

When the program reaches step G200, the contents of the memory are SMOD 1 instead of 0. The program therefore moves from step G200 to step G400 and to step G410, where the program includes a one-minute routine for a wait state.

If the one minute routine, which includes a loop with step G410, has not ended, the program jumps directly to step A5 of step G410. No heating elements are energized during this one minute routine.

When the one minute routine has ended, the program proceeds to step G420, where the memory SMOD is set to 2 and jumps to step A5. The program continues with the next steps. When the program reaches step G400, the contents of the memory are SMOD 2 instead of 1. Therefore, the program goes to step H100.

When the program reaches step H100, the temperature of the inner pot reaches 50 ° C, which is a suitable temperature for soaking rice. In step H105, the program determines whether the contents of the memory are SMOD 2.

If yes, then the program goes to step H110, where microprocessor 108 provides a logic 0 at terminal D2.

In confirmation step H120, the program determines whether the input signal at terminal G2 is logic 1. If yes, this means that the tube has a malfunction, that is

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say the temperature of the inner pot is higher than 160 C.

The program therefore goes to step H125 where the memory MODE is set to 3 in order to put the tube in mode 3. The program then jumps to step A5 to run through a loop in which the electric rice cooker is disconnected from the mains in mode 3.

The electric rice cooker is therefore protected against malfunctions, for example against fire.

If, on the other hand, the input signal at terminal G2 in step H120 is not logic 0, the program goes to step H130, which includes a nine-minute routine.

When the program reaches step H130, the program determines whether the routine has ended. If no, the routine is repeated for nine minutes, alternating with the mains supply connected to the heaters for three seconds and no mains supply for 13 seconds according to the loop with steps H14Ö, H150, H160, H155 and H165.

This repeated cycle maintains the temperature of the inner pot suitable for soaking rice. If the nine minute routine has ended, the program proceeds to step H135. The program sets the memory SMOD to 3 at step H135 and jumps to step A5. When the program reaches step H105, the contents of the memory are SMOD 3. Therefore, the program goes to step 1110, where the program determines whether SMOD is 3 through step 1100. Since the contents of the memory are SMOD 3, the microprocessor 108 a logic 0 at terminal D3 (step 1120) and goes to step 1130.

In step 1130, the program determines whether the input signal at terminal G3 is logic 1. If no, the program jumps to step D100, so that the mains power is supplied to the heating elements by the loop with subroutine TRC1 and the rice is cooked correctly by the heat generated with a power of 850 W.

When the rice has finished cooking and the water in the pot has been used, the temperature of the

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inner pot rise abruptly above 140 ° C. A logic 1 is then supplied to the terminal G3 of the microprocessor 108. Therefore, if the program reaches step 1130, the program goes from step 1130 to step 1140. In steps 1140 and 1150, the microprocessor 108 yields a logic 0 connection L6 and a logic 1 on connection L5. This turns off the cooking indicator diode D and igniting the steam indicator diode D.

In step 1160, the content of the memory SMOD is changed from 3 to 4. Then the program jumps to step A5. When the program reaches step 1110, the program goes to step 1112, because the confirmation in step 1110 is false.

Since the contents of the memory are SMOD 4, the program goes from step 1112 to step 1114 and then jumps to step A5. The program loops through step j 1114 until the three minute routine in step 1114 is ended.

During the three minute routine, the boiling heaters are not energized and the inner pot temperature gradually drops, allowing the cooked rice to steam.

When the three minute routine has ended, the program proceeds to step 1116, where microprocessor 108 sets the memory SMOD to 5. Then the program jumps to step A5. When the program returns to step 1112, the program goes to step J100 because the content of the memory SMOD is not 4 but 5.

The program determines in step J110 whether SMOD is equal to 5. If yes, the program goes to step J120.

In step J120, the program determines whether the three minute routine has ended. If no, the program repeatedly cycles through the loop with steps J130, J140 and the subroutine TRC1 for energizing the boilers for one second and a loop with steps J130 and J131 and subroutine TRC2 for energizing the boilers for eight seconds. During the three minute routine, the steaming of the cooked rice is properly done at a low temperature.

Since the time during which the warming element is energized is one eighth of the time for energizing the boiling elements, the temperature of the inner pot is slightly higher than when it is heated by the warming element alone. The temperature for steaming the cooked rice is therefore slightly higher

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then the keep warm temperature of 70 C. The variation of this temperature corresponds to the interval between t6 and t7 in Fig. 3B, where the variation gradually decreases to the keep warm temperature.

If the routine has ended with a three minute delay in step J120, the program proceeds to step J122, where SMOD is set to 6. The program then jumps to step A5 and continues with the next steps. When the program reaches step J110, SMOD is not equal to 5. The program therefore moves to step J112, which includes a nine-minute routine. When the program reaches step J112, the program determines whether the nine minute routine has ended. If no, the program jumps to step A5 and continues with the loop without energizing the keep warm and cooking heating elements. The temperature of the pot therefore gradually falls and the steaming of the cooked rice takes place in the correct manner. When the nine minute routine in step J112 is ended, the program proceeds to step J114, where MODE is set to 3. The microprocessor 108 provides a logic 0 to terminals D1 (step J116) and L5 (step J118). With a logic 0, both the keep-warm indicator lamp and the steam indicator lamp turn off, indicating that cooking has ended.

The variations of the temperature and energy consumption of the inner pot during cooking are shown in fig.

3B is shown.

The interval between t1 and t2 serves to raise the temperature to a value suitable for properly soaking the rice. For one minute between t2 and t3, the temperature of the pot rises slightly above the appropriate temperature for weeks but gradually decreases to the appropriate temperature,

The time between t3 and t4 is nine minutes, during which the rice is soaked at a constant temperature. During the time interval between t4 and t5, the rice is cooked at constant power. The temperature of the inner pot drops slightly and the cooked rice is steamed between t5 and t6 for three minutes. The interval between t6 and t7 is the three minutes extended by the present invention to steam the cooked rice while keeping the slope of the temperature variation very small.

For nine minutes between t7 and t8, the mains power to all heating elements is interrupted and the temperature of the entire pot decreases with a slight slope, while the steaming of the cooked rice continues.

D. Operation in mode 3

This mode maintains the constant temperature of the inner pot at a suitable level for keeping the pot warm. The function of this mode is to prevent the electric rice cooker from overheating due to a malfunction.

Mode 3 is performed by each of three operating modes. First, it is automatically selected when cooking is finished, as described above. Second, the microprocessor 108 selects mode 3 when reset circuit 109 is operated by a power failure recovery, as described with reference to Fig. 2A. Thirdly, mode 3 is performed when the temperature of the inner pot suddenly rises

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above 160 C as a result of a malfunction.

If mode 3 is selected, as shown in Figure 2B, the microprocessor 108 provides a logic 1 to terminal D3 (step B2), in order to allow 70 ° C for the temperature of the pot to be detected by the temperature detection circuit 101. The microprocessor 108 determines in step B3 whether the input signal at terminal G3 is logic 1. If yes, the program jumps to step A5 and continues through the next loop until the temperature of the inner pot

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below 70 ° C. If the temperature of the pot is below 0 70 C and the input signal on connection G3 is not logical 1, the program goes to the subroutine TRC2 of step C100 to connect the mains supply to the keep-warm element.

The invention is not limited to the exemplary embodiment described above, which can be varied in a number of ways within the scope of the invention. The described exemplary embodiment according to the invention has remarkable practical effects.

Claims (5)

Device for controlling an electric rice cooker for cooking rice, characterized by a temperature detecting means for detecting the temperature of the inner pot of the electric rice cooker, a switching element for a boiling heating element for connecting the AC voltage supply to a heating element for cooking rice in the pot, a switching element for a warming element for connecting the AC voltage supply to a second heating element for keeping the cooked rice warm at a predetermined temperature, a switching signal generating means for generating a switching signal, so that the switching element is switched in synchronism with the zero crossing of the AC voltage and a microprocessor, which controls the switching means in response to all said means and a fixed program. Device according to claim 1, characterized in that the switching means comprises a circuit for deciding whether the voltage of the mains is 220 or 100 V, the microprocessor controlling the switching means such that a constant power is supplied to each of the heating elements independent of the voltage of the mains. Device according to claim 1 or 2, characterized by a mode selector for selecting a cooking method. Device according to claim 1, 2 or 3, characterized in that the temperature detecting member is provided with a thermistor (Th) and a resistor (R20) connected in series with it, two comparators (IC1 and IC2), the inverting of which inputs together are connected in parallel to the thermistor (Th) and whose outputs are connected to terminals (G2 and G3) of the microprocessor (108), a first voltage divider with two resistors (R18 and R19), the node of which is connected to the non-inverting input of the comparator (IC1), a second voltage divider with resistors (R16 and R17), the node of which is connected to the non-inverting input of the comparator (IC2), a first temperature setting circuit with the series circuit of a diode (D17) and a resistor (R19), the anode of the diode (D17) is connected to the non-inverting input of IC1 and a terminal of the resistor (R9) is connected to terminal (D3) of the microprocessor ( 108), a second temperature setting circuit with the series connection of a diode (D18) and a resistor (R10), the anode of the diode (D18) being connected to the non-inverting input of IC2 and a connection of the resistor (R10) being connected to a connection (D2) of the microprocessor (108). Method of controlling an electric rice cooker for cooking rice, characterized in that a repetitive "on" and "off" switching step for repeatedly switching the mains supply for the cooking heating elements on and off is carried out so that the temperature of the inner pot is increased by a slight slope, interrupting the mains supply of the boiling heating elements during a first predetermined interval, which is necessary for the temperature of the inner pot to drop from the first predetermined temperature to a second predetermined temperature, wherein a second repetitive "on" and "off" switching step for repeatedly switching the mains supply of the cooking heating elements on and off, in order to maintain a constant temperature of the inner pot during a second predetermined interval, the mains supply without any interval at the boiling heating elements are supplied to maintain the temperature from the inner pot to a third predetermined temperature, whereby the rice is cooked, interrupting the mains supply of the cooking heating elements during a third predetermined interval, whereby a third switching step for switching the mains supply "on" and "off" for alternately connecting the boiling heating elements and the keeping warm element and the mains supply for the keeping warm element is controlled such that the temperature of the inner pot is maintained at a fourth predetermined temperature.